Superconducting device with asymmetric impedance

ABSTRACT

An electronic component having an asymmetric impedance is provided. The component includes first, second and third branches that connect at a common node. The component includes a first portion of superconducting material disposed along the first branch and a second portion of superconducting material disposed along the second branch. The component includes a first device disposed along the first branch and configured to transition the second portion of the superconducting material to a non-superconducting state when a current between a first terminal of the first device and a second terminal of the first device exceeds a first threshold value and a second device disposed along the second branch and configured to transition the first portion of the superconducting material to a non-superconducting state when a current between a first terminal of the second device and a second terminal of the second device exceeds a second threshold value.

PRIORITY AND RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 17/033,337, filed Sep. 25, 2020, entitled “Superconducting Device with Asymmetric Impedance,” which claims priority to U.S. Provisional Patent Application No. 62/906,680, filed Sep. 26, 2019, entitled “Superconducting Device with Asymmetric Impedance,” each of which is hereby incorporated by reference in its entirety.

This application relates to U.S. patent application Ser. No. 16/136,124, filed Sep. 19, 2018, entitled “Methods and Devices for Impedance Multiplication,” now U.S. Pat. No. 10,461,445, and U.S. patent application Ser. No. 16/107,143, filed Aug. 21, 2018, entitled “Superconductor-to-Insulator Devices,” now U.S. Pat. No. 10,573,800, each of which is incorporated by reference in its entirety.

TECHNICAL FIELD

This relates generally to electronic devices (e.g., diodes) having an asymmetric conductance (e.g., asymmetric impedance) between terminals and, more specifically, to diodes that operate based on the properties of superconducting materials.

BACKGROUND

Impedance is a measure of the opposition to current flow in an electrical circuit. Superconductors are materials capable of operating in a superconducting state with zero electrical resistance under particular conditions. Additionally, in some circumstances, superconductors have high impedance while in a non-superconducting state. Moreover, superconductors generate heat when operating in a non-superconducting state, as well as when transitioning from a superconducting state to a non-superconducting state.

Metals and other materials with non-zero resistance generate resistive heat when a current flows through them. The amount of heat generated is based on a current density, and thus is based on a width of a wire carrying the current.

SUMMARY

The present disclosure provides thin-film diode devices based on superconducting materials, thereby utilizing advantages of superconducting materials (e.g., zero resistance under certain conditions). In addition, diodes that are superconducting can be integrated more easily (e.g., monolithically) with other superconducting components in circuits and devices. Such circuits and devices are often used for making sensitive measurements. For example, superconducting circuits play a critical role in superconducting quantum interference devices (SQUIDs). Superconducting components also play an important role in sensitive optical measurements. For these purposes, there is a need for diodes whose operating principles are based on the properties of superconducting materials.

To that end, some embodiments of the present disclosure provide an electronic component. The electronic component includes first, second and third branches that connect at a common node. The electronic component includes a first portion of superconducting material disposed along the first branch and a second portion of superconducting material disposed along the second branch. The electronic component includes a first device disposed along the first branch. The first device is configured to transition the second portion of the superconducting material to a non-superconducting state when a current between a first terminal of the first device and a second terminal of the first device exceeds a first threshold value. The electronic component includes a second device disposed along the second branch. The second device is configured to transition the first portion of the superconducting material to a non-superconducting state when a current between a first terminal of the second device and a second terminal of the second device exceeds a second threshold value.

Further, some embodiments of the present disclosure provide another electronic component. The electronic component has a first end and a second end. The electronic component includes first, second and third branches that connect at a common node. The first branch terminates at the first end and the third branch terminates at the second end. The first branch includes a first portion of superconducting material and a first device coupled in series. The second branch includes a second portion of superconducting material and a second device coupled in series. The second device is configured to control a state of the first portion of superconducting material and the first device is configured to control a state of the second portion of superconducting material, such that a first signal applied to the first end flows to the second end while the first portion of superconducting material remains in a superconducting state, and a second signal applied to the second end causes a current to flow through the second device and transition the first portion of superconducting material from the superconducting state to a non-superconducting state.

Thus, devices and circuits are provided with methods for operating superconducting components, thereby increasing the effectiveness and efficiency of such circuits and devices.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the various described embodiments, reference should be made to the Detailed Description below, in conjunction with the following drawings in which like reference numerals refer to corresponding parts throughout the figures.

FIG. 1 is a schematic representation of an electronic component with asymmetric impedance, in accordance with some embodiments.

FIGS. 2A-2C are schematic representations of states of the electronic component of FIG. 1 as a signal is applied in one direction across the electronic component, in accordance with some embodiments.

FIGS. 3A-3C are schematic representations of states of the electronic component of FIG. 1 as a signal is applied in the other direction across the electronic component, in accordance with some embodiments.

FIG. 4 is a schematic diagram of an impedance amplifier comprising a resistive layer that controls a resistance of a variable resistor (e.g., a superconducting layer), in accordance with some embodiments.

FIG. 5 is a schematic diagram of an impedance amplifier comprising a piezoelectric layer (e.g., a piezoelectric component) that controls a resistance of a variable resistor (e.g., a superconducting layer), in accordance with some embodiments.

FIGS. 6A-6B are schematic diagrams of an impedance amplifier comprising a superconducting layer that controls a resistance of a variable resistor (e.g., a superconducting layer), in accordance with some embodiments.

FIG. 7 is a schematic diagram of an impedance amplifier comprising a component (e.g., a resistive or superconducting component) that controls a resistance of a superconducting component (e.g., a superconducting layer), in accordance with some embodiments.

DETAILED DESCRIPTION

Reference will now be made in detail to embodiments, examples of which are illustrated in the accompanying drawings. In the following detailed description, numerous specific details are set forth in order to provide a thorough understanding of the various described embodiments. However, it will be apparent to one of ordinary skill in the art that the various described embodiments may be practiced without these specific details. In other instances, well-known methods, procedures, components, circuits, and networks have not been described in detail so as not to unnecessarily obscure aspects of the embodiments.

Many modifications and variations of this disclosure can be made without departing from its spirit and scope, as will be apparent to those skilled in the art. The specific embodiments described herein are offered by way of example only, and the disclosure is to be limited only by the terms of the appended claims, along with the full scope of equivalents to which such claims are entitled.

As used herein, a “superconducting circuit” or “superconductor circuit” is a circuit having one or more superconducting materials. For example, a superconductor switch circuit is a switch circuit that includes one or more superconducting materials. As used herein, a “superconducting” material is a material that is capable of operating in a superconducting state (under particular conditions). For example, a superconducting material is a material that operates as a superconductor (e.g., operates with zero electrical resistance) when cooled below a particular temperature (e.g., a threshold temperature) and having less than a threshold current flowing through it. A superconducting material is also sometimes called a superconduction-capable material. In some embodiments, the superconducting materials operate in an “off” state when supplied with a current less than a threshold current, and operate in an “on” state when supplied with a current greater than the threshold current. In some embodiments, the superconducting materials can operate in a non-superconducting state during which the materials have a non-zero electrical resistance (e.g., a resistance in the range of one thousand to ten thousand ohms). For example, a superconducting material supplied with a current greater than a threshold superconducting current for the superconducting material transitions from a superconducting state having zero electrical resistance to a non-superconducting state having non-zero electrical resistance.

As used herein, a “wire” is a section of material configured for transferring electrical current. In some embodiments, a wire includes a section of material conditionally capable of transferring electrical current, e.g., a wire made of a superconducting material that is capable of transferring electrical current while the wire is maintained at a temperature below a threshold temperature. As another example, a wire made of semiconducting material is capable of transferring electrical current while the wire is maintained at a temperature above a freeze-out temperature. A cross-section of a wire (e.g., a cross-section that is perpendicular to a length of the wire) optionally has a regular (e.g., flat or round) shape or an irregular shape. While some of the figures show wires having rectangular shapes, any shape could be used. In some embodiments, a length of a wire is greater than a width or a thickness of the wire (e.g., the length of a wire is at least 5, 6, 7, 8, 9, or 10 times greater than the width and the thickness of the wire). In some cases, a wire is a section of a superconducting layer.

It should be noted that, although certain embodiments are described below in terms of resistances (e.g., R₁, R₂, R_(L)), in some circumstances, the devices, components, and methods described herein are used in an alternating current (AC) environment, in which case analogous considerations apply with respect to the more general property of impedance.

FIG. 1 is a schematic representation of an electronic component 100 with asymmetric impedance, in accordance with some embodiments. In some embodiments, electronic component 100 is integrated on a common substrate 103 (e.g., the same substrate). For example, electronic component 100 is a thin-film device fabricated on substrate 103. In some embodiments, various components shown in electronic component 100 comprise instances of layers deposited on substrate 103. In some embodiments, as shown in FIG. 1 , the layers are co-planar (e.g., the components are horizontally adjacent to each other). In some embodiments, various layers are stacked, with vias and other appropriate components interconnecting the various components shown in FIG. 1 .

Electronic component 100 includes a first branch 104 a, a second branch 104 b, and a third branch 104 c. The first, second, and third branches 104 connect at a common node 101. A first portion of superconducting material 106 a is disposed along the first branch 104 a and a second portion of superconducting material 106 b is disposed along the second branch 104 b. In some embodiments, the first portion of superconducting material 106 a and the second portion of superconducting material 106 b comprise the same superconducting material (e.g., distinct portions or instances of a common layer of superconducting material deposited on substrate 103). In some embodiments, the first portion of superconducting material 106 a and the second portion of superconducting material 106 b comprise different superconducting materials (e.g., different layers of superconducting material on the common substrate 103). In some embodiments, the first portion of superconducting material 106 a and the second portion of superconducting material 106 b comprise superconducting nanowires (e.g., wires with a width less than a micron).

A first device 108 a is disposed along the first branch 104 a. The first device 108 a is configured to transition the second portion of superconducting material 106 b to a non-superconducting state (e.g., resistive) state when a current between a first terminal 109 a of the first device 108 a and a second terminal 109 b of the first device 108 a exceeds a first threshold value. In some embodiments, the first device 108 a is electrically insulated from the second portion of superconducting material 106i b.

In some embodiments, first device 108 a and the second portion of the superconducting material 106 b comprise a first impedance amplifier 202 a (labeled in FIG. 2A). In some embodiments, the first impedance amplifier 202 a is in an “on” state when the current between the first terminal 109 a of the first device 108 a and the second terminal 109 b of the first device 108 a exceeds the first threshold value. In some embodiments, the first impedance amplifier 202 a is in an “off” state when the current between the first terminal 109 a of the first device 108 a and the second terminal 109 b of the first device 108 a does not exceed the first threshold value. In some embodiments, when the first impedance amplifier 202 a is in an “on” state, the impedance of the second portion of the superconducting material 106 b is greater than the impedance of the first device 108 a. In some embodiments, when the first impedance amplifier 202 a is in an “off” state, the impedance of the first device 108 a is greater than the impedance of the second portion of the superconducting material 106 b. Thus, in some embodiments, the second portion of superconducting material 106 b is a variable resistor (e.g., having a resistance that depends on whether the second portion of superconducting material 106 b is in a superconducting state or a non-superconducting state).

For example, the first device 108 a is a heater (e.g., a resistive heating element, as described below with reference to FIG. 4 , or a superconducting component configured to transition to a non-superconducting state, as described below with reference to FIG. 6 ). In some embodiments, as explained in greater detail below, in the absence of current applied to the first device 108 a, the second portion of the superconducting material 106 b is maintained at a temperature below its threshold temperature (e.g., critical temperature). The first device 108 a is electrically isolated from but thermally coupled to the second portion of the superconducting material 106 b such that when a current that exceeds the first threshold value is applied across the first device 108 a, the second portion of the superconducting material 106 b is warmed above its threshold temperature, causing it to transition to a non-superconducting state. In some embodiments, the resistance of the second portion of the superconducting material 106 b when in the non-superconducting state is greater than the resistance of the first device 108 a.

Similarly, a second device 108 b is disposed along the second branch 104 b and configured to transition the first portion of the superconducting material 106 a to a non-superconducting state when a current between a first terminal of the second device 108 b and a second terminal of the second device 108 b exceeds a second threshold value. In some embodiments, the second device 108 b is electrically insulated from the first portion of superconducting material 106 a.

In some embodiments, the second device 108 b is also a heater (e.g., a resistive heating element) and thus operates in an analogous manner to first device 108 a, as described above. In some embodiments, the second threshold value and the first threshold value are the same (e.g., first device 108 a and second device 108 b are distinct but are otherwise analogous devices). In some embodiments, the first threshold value and the second threshold value are different. For example, the first threshold value and the second threshold values can be selected to tune a range of operating conditions, as described below.

In some embodiments, the second device 108 b and the first portion of superconducting material 106 a comprise a second impedance amplifier 202 b (e.g., analogous to the first impedance amplifier 202 a, described above, but optionally configured such that the second threshold value is different from the first threshold value). Thus, in some embodiments, the first portion of superconducting material 106 a is a variable resistor (e.g., having a resistance that depends on whether the first portion of superconducting material 106 a is in a superconducting state or a non-superconducting state).

In some embodiments, the first branch 104 a has an effective resistance R₂ when the first portion of superconducting material 106 a is in a superconducting state. In some embodiments, the effective resistance R₂ includes one or more resistors. In some embodiments, the effective resistance R₂ includes an inherent resistance of the first branch 104 a (e.g., a resistance of a wire comprising the first branch 104 a). In some embodiments, the first branch 104 a includes a resistor connected in series with the first device 108 a. In some embodiments, the resistance R₂ is or includes the resistance of the first device 108 a (which, as noted above, may be a resistive heater).

In some embodiments, the second branch 104 b has an effective resistance R₁ when the second portion of superconducting material 106 b is in a superconducting state. In some embodiments, the effective resistance R₁ includes one or more resistors. In some embodiments, the effective resistance R₁ includes an inherent resistance of the second branch 104 b (e.g., a resistance of a wire comprising the second branch 104 b). In some embodiments, the second branch 104 b includes a resistor connected in series with the second device 108 b. In some embodiments, the resistance R₁ is or includes the resistance of the second device 108 b (which, as noted above, may be a resistive heater). In some embodiments, the resistance R₂ of the first branch 104 a and the resistance R₁ of the second branch 104 b are selected to define a predefined range of operating conditions (e.g., applied voltages, currents, and loads) under which electronic component 100 has an asymmetric impedance.

To that end, in some embodiments, the first branch 104 a terminates at a first end 102 a of the electronic component 100 and the third branch 104 c terminates at a second end 102 b of the electronic component 100. Under the predefined range of operating conditions (e.g., with a predefined load coupled with the electronic component 100 and for a predefined range of applied currents and/or voltages), the electronic component 100 has a different impedance between the first end 102 a and the second end 102 b as compared to an impedance between the second end 102 b and the first end 102 a (e.g., electronic component 100 has an asymmetric impedance). Thus, in some embodiments, electronic component 100 acts as a diode.

In some embodiments, the second portion of superconducting material 106 b and the second device 108 b are coupled in series. The second device 108 b is configured to control a state of the first portion of superconducting material 106 a (e.g., control whether the first portion of superconducting material 106 a is in a superconducting state or a non-superconducting state). Similarly, the first device 108 a is configured to control a state of the second portion of superconducting material 106 b (e.g., control whether the first portion of superconducting material 106 a is in a superconducting state or a non-superconducting state). A first signal applied to the first end 102 a flows to the second end 102 b while the first portion of superconducting material 106 a remains in a superconducting state, and a second signal applied to the second end 102 b causes a current to flow through the second device 108 b and transition the first portion of superconducting material 106 a from the superconducting state to a non-superconducting state.

Note that, in some embodiments, electronic component 100 is fully passive (e.g., does not require current or voltage biasing). Thus, in some embodiments, electronic component 100 does not consume power when not in use.

FIGS. 2A-2C are schematic representations of states of the electronic component 100 as a signal is applied in a first direction across the electronic component 100 (e.g., from the third branch 104 c toward the first branch 104 a), in accordance with some embodiments. Note that, in use, the electronic component 100 is maintained at cryogenic temperatures (e.g., temperatures below the critical temperature for any or all of the superconducting components employed by electronic component 100).

In the example shown in FIGS. 2A-2C, the first branch 104 a is coupled in series with a load 204 (having a resistance R_(L)). In some embodiments, the load 204 comprises a load from circuitry external to electronic component 100. In some embodiments, the resistance R_(L) of the load 204 is a predefined load. For example, the electronic component 100 is configured to operate, as described herein, when coupled to a load that is within a predefined range of operating loads (e.g., through selection and configuration of threshold currents for the first impedance amplifier 202 a and the second impedance amplifier 202 b).

In some embodiments, load 204 is integrated on the same substrate as electronic component 100 (e.g., substrate 103, FIG. 1 ).

FIG. 2A illustrates electronic component 100 at a first time (t=t₀). At the first time, no voltage V is applied between the third branch 104 c and ground (thus, no signal is applied in a first direction across the electronic component 100 (e.g., from the third branch 104 c toward the first branch 104 a)).

FIG. 2B illustrates the electronic component 100 at a second time t=t₁ after the first time. The second time is immediately after (e.g., upon) application of a non-zero voltage V₁ between the third branch 104 c and ground (e.g., the second time t=t₁ is within a response time of the electronic component 100, such that the electronic component 100 has not yet responded to the application of the non-zero voltage V₁). In this example, the opposite ends of the first and second branches 104 (i.e., opposite the common node 101 from the third branch 104 c) are coupled to ground. For example, the first branch 104 a is coupled to ground through the load 204 and the second branch 104 b is coupled directly to ground. Thus, a signal is applied in the first direction across the electronic component 100 (e.g., from the third branch 104 c toward the first branch 104 a). The application of the voltage V₁ results in a current I₁ that is divided between the first branch 104 a and the second branch 104 b in accordance with the respective resistances of the two branches. For example, a first portion I₂ of the current I₁ is directed along the first branch 104 a and a second portion I₃ of the current I₁ is directed along the second branch 104 b.

FIG. 2C illustrates the electronic component 100 at a third time t=t₂ after the second time. The third time is more than a response time after application of the voltage V₁ shown in FIG. 2B. In this example, the first portion I₂ of the current I₁ exceeds the first threshold value for the first device 108 a. Thus, in response to the first portion I₂ of the current I₁, first device 108 a transitions the second portion of superconducting material 106 b to a non-superconducting state (represented by black fill). In some embodiments, the non-superconducting state is an insulating state. In some embodiments, the non-superconducting state is a resistive state.

Further, in this example, the second portion I₃ of the current I₁ exceeds the second threshold value for the second device 108 b. Thus, in response to the second portion I₃ of the current I₁, second device 108 b transitions the first portion of superconducting material 106 a to a non-superconducting state. In some embodiments, the non-superconducting state is an insulating state. In some embodiments, the non-superconducting state is a resistive state.

Thus, when a signal is applied in the first direction across the electronic component 100, for at least a predefined range of operating conditions (e.g., predefined ranges for load 204 and voltage V₁), the electronic component 100 transitions to a non-superconducting state (e.g., an insulating or resistive state). In some embodiments, zero current or close to zero current flows through electronic component 100 when electronic component 100 is in an insulating state (e.g., as shown in FIG. 2C).

FIGS. 3A-3C are schematic representations of states of the electronic component 100 as a signal is applied in the other direction (e.g., a second direction) across the electronic component 100 (e.g., from the first branch 104 a toward the third branch 104 c), in accordance with some embodiments. In the example shown in FIGS. 3A-3C, the third branch 104 c is coupled in series with load 204 (having a resistance R_(L)).

Note that, in use, the electronic component 100 is maintained at cryogenic temperatures (e.g., temperatures below the critical temperature for any or all of the superconducting components employed by electronic component 100).

FIG. 3A illustrates electronic component 100 at a first time (t=t₀). At the first time, no voltage V is applied between the first branch 104 a and ground (thus, no signal is applied in the second direction across the electronic component 100 (e.g., from the third branch 104 c toward the first branch 104 a)).

FIG. 3B illustrates the electronic component 100 at a second time t=t₁ after the first time. The second time is immediately after (e.g., upon) application of a non-zero voltage V₁ between the first branch 104 a and ground (e.g., the second time t=t₁ is within a response time of the electronic component 100, such that the electronic component 100 has not yet responded to the application of the non-zero voltage V₁).

In this example, the opposite ends of the second and third branches 104 (i.e., opposite the common node 101 from the first branch 104 a) are coupled to ground. For example, the third branch 104 c is coupled to ground through the load 204 and the second branch 104 b is coupled directly to ground. Thus, a signal is applied in the second direction across the electronic component 100 (e.g., from the first branch 104 a toward the third branch 104 c). The application of the voltage V₁ results in a current I₁′ that is divided between the second branch 104 b and the third branch 104 c in accordance with the respective resistances of the two branches. For example, a first portion I₂′ of the current I₁′ is directed along the second branch 104 a and a third portion I₃′ of the current I₁′ is directed along the third branch 104 c.

FIG. 3C illustrates the electronic component 100 at a third time t=t₂ after the second time. The third time is more than a response time after application of the voltage V₁ shown in FIG. 3B. In this example, the current I₁′ exceeds the first threshold value for the first device 108 a. Thus, in response to the current I₁′, first device 108 a transitions the second portion of superconducting material 106 b to a non-superconducting state (represented by black fill). In some embodiments, the non-superconducting state is an insulating state (e.g., almost no current flows through the second branch 104 b when the second portion of superconducting material 106 b is in an insulating state). In some embodiments, the non-superconducting state is a resistive state.

In this example, the first portion I₂′ of the current I₁′ does not exceed the second threshold value for the second device 108 b. Thus, in response to the first portion I₂′ of the current I₁′, second device 108 b does not transition the first portion of superconducting material 106 a to a non-superconducting state. Rather, the first portion of superconducting material 106 a remains in a superconducting state. With the second portion of superconducting material 106 b in a non-superconducting state, a resulting current I_(f) flows through the electronic component 100 (e.g., from the first branch 104 a to the third branch 104 c, based on the serial combination of R₂ and R_(L)).

Thus, when a signal is applied in the second direction across the electronic component 100, for at least a predefined range of operating conditions (e.g., predefined ranges for load 204 and voltage V₁), a path through the electronic component 100 remains in a superconducting state allowing current to flow. In some embodiments, the device state shown in FIG. 3C, with current continuing to flow through the first branch 104 a but not the second branch 104 b of device 100, is a steady state of the device 100 (as used herein, the term steady-state refers to a DC behavior of the system or circuit).

Note that the load 204 and the voltage V₁ are assumed to be the same in FIGS. 3A-3C as in FIGS. 2A-2C. Thus, for the same load 204 and voltage V₁, electronic component 100 has a different impedance depending on the direction along which the signal is applied (e.g., under the predefined range of operating conditions, the electronic component 100 has a different impedance between the first end and the second end as compared to an impedance between the second end and the first end). In some embodiments, various device parameters can be used to tune or adapt the predefined range of operating conditions. For example, in some embodiments, the first resistance R₁ and the second resistance R₂ are selected to define the predefined range of operating conditions (e.g., by controlling how current is divided between the various branches when the electronic component 100 is coupled with a predefined load).

FIGS. 4-7 illustrate example embodiments of the impedance amplifiers described above (e.g., impedance amplifiers 202 a and 202 b). One of skill in the art, however, having had the benefit of this disclosure, will recognize that other impedance amplifiers are possible and fall within the scope of the appended claims.

FIG. 4 is a schematic diagram of an impedance amplifier 410 comprising a resistive layer 406 (e.g., a resistive heater) that controls a resistance of a variable resistor (e.g., a superconducting layer 408), in accordance with some embodiments. In some embodiments, the impedance amplifier 410 includes an insulating layer 404 that electrically-insulates, but thermally couples, resistive layer 406 from superconducting layer 408. In some embodiments, the impedance amplifier 410 further includes a protective layer 412. The impedance amplifier 410 is fabricated on a substrate 402.

In some embodiments, the devices 108, described above, may comprise resistive layer 406, while the portions of superconducting material 106, described above, may comprise superconducting layer 408.

In some embodiments, in response to receiving a current, resistive layer 406 generates resistive heat. In some embodiments, impedance amplifier 410 is configured such that, when resistive layer 406 receives a current above a threshold value (e.g., the first threshold value of first device 108 a or the second threshold value of second device 108 b, described above), the resistive layer 406 generates sufficient heat (e.g., enough heat transfers to superconducting layer 408) such that the superconducting layer 408 transitions to a non-superconducting (e.g., insulating) state (e.g., by increasing a temperature of the superconducting layer 408 above a superconducting threshold temperature for the superconducting layer 408). In the non-superconducting state, the superconducting layer 408, has a higher resistance than the resistive layer 406, and thus impedance amplification is achieved.

FIG. 5 is a schematic diagram of an impedance amplifier 510 comprising a piezoelectric layer 504 (e.g., a piezoelectric component) that controls a resistance of a variable resistor (e.g., a superconducting layer 506), in accordance with some embodiments. The impedance amplifier 510 is fabricated on a substrate 502. In some embodiments, the impedance amplifier 510 further includes a protective layer 512. Note that, in various embodiments, the piezoelectric layer 504 may be below the superconducting layer 506 and may in fact comprise the substrate 502 (e.g., the substrate may be a piezoelectric substrate).

In some embodiments, the devices 108, described above, may comprise piezoelectric layer 504, while the portions of superconducting material 106, described above, may comprise superconducting layer 506.

In some embodiments, when piezoelectric layer 504 receives a current above a threshold value (e.g., the first threshold value of first device 108 a or the second threshold value of second device 108 b, described above), superconducting layer 506 undergoes a non-thermal phase transition from a superconducting state to a non-superconducting state (e.g., insulating state) in response to a strain applied by piezoelectric layer 504. In some embodiments, the superconducting layer 506 is adapted to transition between the superconducting state and the non-superconducting state, in response to a strain applied by piezoelectric layer 504, by having a thickness slightly above a superconducting thickness threshold, e.g., within 5 nanometers (nm), 10 nm, or 20 nm of the superconducting thickness threshold.

Thus, when piezoelectric layer 504 receives a current above the threshold value, piezoelectric layer 504 generates a strain in superconducting layer 506 (e.g., by virtue of being epitaxial or lattice-matched with superconducting layer 506). In some embodiments, impedance amplifier 510 is configured such that, when piezoelectric layer 504 receives a current above the threshold value, enough strain is applied to superconducting layer 506 to transition the superconducting layer 506 to a non-superconducting (e.g., insulating) state. In some embodiments, the superconducting layer 506, when in the non-superconducting state, has a higher resistance than the piezoelectric layer 504, and thus impedance amplification is achieved.

FIGS. 6A-6B are schematic diagrams of an impedance amplifier 610 comprising a first superconducting layer 606 that controls a resistance of a variable resistor (e.g., a second superconducting layer 608), in accordance with some embodiments. The impedance amplifier 610 is fabricated on a substrate 602. In some embodiments, the impedance amplifier 610 includes an insulating layer 604 that electrically-insulates the first superconducting layer 606 from the second superconducting layer 608. In some embodiments, the impedance amplifier 610 further includes a protective layer 612.

In some embodiments, the devices 108, described above, may comprise first superconducting layer 606, while the portions of superconducting material 106, described above, may comprise second superconducting layer 608.

In some embodiments, the first superconducting layer 606 is configured to transition to a non-superconducting state in response to receiving a current above a threshold value (e.g., the first threshold value of first device 108 a or the second threshold value of second device 108 b, described above). In some embodiments, the second superconducting layer 608 is configured to transition to a non-superconducting state in response to the first superconducting layer 606 transitioning to a non-superconducting state. For example, in some embodiments, the first superconducting layer 606 generates resistive heat in the non-superconducting state (e.g., resistive state) that transfers to the second superconducting layer 608. In some embodiments, impedance amplifier 610 is configured such that, when the first superconducting layer 606 receives a current above the threshold value, enough heat transfers to second superconducting layer 608 to transition the second superconducting layer 608 to a non-superconducting (e.g., insulating) state. In the non-superconducting state, the second superconducting layer 608 has a higher resistance than the first superconducting layer 606, and thus impedance amplification is achieved.

In some embodiments, the first superconducting layer 606 has one or more geometric features, such as constriction 614, that lower the threshold value for transitioning to a non-superconducting state.

FIG. 7 is a schematic diagram of an impedance amplifier 700 comprising a component 704 that controls a resistance of a variable resistor (e.g., a superconducting component 702), in accordance with some embodiments. In some embodiments, component 704 is a superconductor, while in some other embodiments, component 704 is a non-superconducting component, e.g., a resistive component formed from a metal material, a semiconducting material or any other resistive material. In some embodiments, component 704 comprises a metal and/or doped semiconductor. In embodiments in which component 704 comprises a metal or doped semiconductor, some heat is generated through region 718 of component 704 as current flows between terminals 714 and 716. In some embodiments, component 704 and superconducting component 702 are co-planer (e.g., formed from layers of material that are next to each other). In some embodiments, component 704 and superconducting component 702 are distinct instances of a common layer of material (e.g., superconducting material) deposited on a substrate.

FIG. 7 further shows terminals 706 and 708 connected to the superconducting component 702 and terminals 714 and 716 connected to the component 704. Superconducting component 702 includes constriction region 701 adjacent to region 718 of component 704, which thermally-couples components 702 and 704. Although not shown in FIG. 7 , in some embodiments, the components 702 and 704 are thermally coupled by a coupling component.

In some embodiments, each of the devices 108, described above, may comprise an instance of component 704, while each of the portions of superconducting material 106, described above, may comprise an instance of superconducting component 702.

In some embodiments, impedance amplifier 700 is configured such that, when component 704 receives a current above a threshold value (e.g., the first threshold value of first device 108 a or the second threshold value of second device 108 b, described above), the component 704 generates sufficient heat (e.g., enough heat transfers to superconducting component 702) such that the superconducting component 702 transitions to a non-superconducting (e.g., insulating) state (e.g., by increasing a temperature of the superconducting component 702 above a superconducting threshold temperature for the superconducting component 702). For example, in embodiments in which component 704 comprises a superconductor, a current above the threshold value transitions the region 718 to a non-superconducting state, which generates heat and transitions the constriction region 701 to a non-superconducting state. In the non-superconducting state, the superconducting component 702 has a higher resistance than the resistive layer 406, and thus impedance amplification is achieved.

In some embodiments, only a portion of the component 704, region 718, is in close proximity to the superconducting component 702. In some circumstances, having only a portion of the component 704 in proximity to the superconducting component 702 allows for more control over the heat transfer between the components 702 and 704 and reduces heat dissipation effects of the component 704 by isolating the region 718.

In the embodiments, the superconducting components or regions that are positioned adjacent to each other so as to allow the transfer of heat from one to the other are, at the same time, positioned so as to inhibit (e.g., prevent) cooper pair and/or electron tunneling between those superconducting components or regions (e.g., they are positioned 10 nm, 100 nm, or more apart).

One of skill in the art will appreciate that various other methods and devices for impedance amplification and multiplication may be used. For example, additional embodiments of impedance amplifiers are described in U.S. patent application Ser. No. 16/136,124, entitled “Methods and Devices for Impedance Multiplication,” filed Sep. 19, 2018 and U.S. patent application Ser. No. 16/107,143, entitled “Superconductor-to-Insulator Devices,” filed Aug. 21, 2018, each of which is incorporated by reference in its entirety.

It will also be understood that, although the terms first, second, etc. are, in some instances, used herein to describe various elements, these elements should not be limited by these terms. These terms are only used to distinguish one element from another. For example, a first current could be termed a second current, and, similarly, a second current could be termed a first current, without departing from the scope of the various described embodiments. The first current and the second current are both currents, but they are not the same condition unless explicitly stated as such.

The terminology used in the description of the various described embodiments herein is for the purpose of describing particular embodiments only and is not intended to be limiting. As used in the description of the various described embodiments and the appended claims, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will also be understood that the term “and/or” as used herein refers to and encompasses any and all possible combinations of one or more of the associated listed items. It will be further understood that the terms “includes,” “including,” “comprises,” and/or “comprising,” when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

As used herein, the term “if” is, optionally, construed to mean “when” or “upon” or “in response to determining” or “in response to detecting” or “in accordance with a determination that,” depending on the context. Similarly, the phrase “if it is determined” or “if [a stated condition or event] is detected” is, optionally, construed to mean “upon determining” or “in response to determining” or “upon detecting [the stated condition or event]” or “in response to detecting [the stated condition or event]” or “in accordance with a determination that [a stated condition or event] is detected,” depending on the context.

The foregoing description, for purpose of explanation, has been described with reference to specific embodiments. However, the illustrative discussions above are not intended to be exhaustive or to limit the scope of the claims to the precise forms disclosed. Many modifications and variations are possible in view of the above teachings. The embodiments were chosen in order to best explain the principles underlying the claims and their practical applications, to thereby enable others skilled in the art to best use the embodiments with various modifications as are suited to the particular uses contemplated. 

What is claimed is:
 1. An electronic component, comprising: first, second and third branches that connect at a common node; a first portion of superconducting material disposed along the first branch; a second portion of superconducting material disposed along the second branch, wherein: the first branch terminates at a first end of the electronic component and the third branch terminates at a second end of the electronic component; and under a predefined range of operating conditions: a first current applied along the third branch is divided between the first branch and the second branch such that the divided first current through the second branch transitions the first portion of the superconducting material to a non-superconducting state and the divided first current through the first branch transitions the second portion of the superconducting material to a non-superconducting state; and a second current applied along the first branch is divided between the second branch and the third branch such that the first portion of the superconducting material remains in a superconducting state.
 2. The electronic component of claim 1, wherein: under the predefined range of operating conditions, the electronic component has a different impedance between the first end and the second end as compared to an impedance between the second end and the first end.
 3. The electronic component of claim 2, wherein, under the predefined range of operating conditions: the first current applied along the third branch is divided between the first branch and the second branch such that the divided first current through the second branch exceeds a threshold value for transitioning the first portion of the superconducting material to the non-superconducting state; and the second current applied along the first branch is divided between the second branch and the third branch such that the divided second current through the second branch does not exceed the threshold value for transitioning the first portion of the superconducting material to the non-superconducting state.
 4. The electronic component of claim 3, wherein, under the predefined range of operating conditions: the first current divided through the first branch exceeds a threshold value for transitioning the second portion of the superconducting material to the non-superconducting state; and the second current applied along the first branch exceeds the threshold value for transitioning the second portion of the superconducting material to the non-superconducting state.
 5. The electronic component of claim 2, further including: a first resistor connected in series with the first portion of superconducting material in the first branch, the first resistor having a first resistance; and a second resistor connected in series with the second portion of superconducting material in the second branch, the second resistor having a second resistance; wherein the first resistance and the second resistance are selected to define the predefined range of operating conditions.
 6. The electronic component of claim 1, further comprising a first heater disposed along the first branch configured to heat the second portion of superconducting material disposed along the second branch.
 7. The electronic component of claim 1, wherein the electronic component is a thin-film device fabricated on a substrate.
 8. The electronic component of claim 7, wherein the first portion of superconducting material and the second portion of superconducting material are distinct portions of a common layer of the superconducting material.
 9. The electronic component of claim 7, wherein the first portion of superconducting materi al is a first superconducting nanowire. 